A Conceptual Framework for Organizing Active Learning Experiences in Biology Instruction

Introductory biology courses form a cornerstone of undergraduate instruction. However, the predominantly used lecture approach fails to produce higher-order biology learning. Research shows that active learning strategies can increase student learning, yet few biology instructors use all identified active learning strategies. In this paper, we present a framework to design biology instruction that incorporates all active learning strategies. We review active learning research in undergraduate biology courses, present a framework for organizing active learning strategies, and provide clear implications and future research for designing instruction in introductory undergraduate biology courses.     

CREDENTIALS NEEDED FOR TEACHING BIOLOGY AND CHEMISTRY IN THE COMMUNITY COLLEGE

Biology and chemistry instructors at 50 institutions within th North Carolina Community College System were surveyed concerning the types of courses they teach, the diversity of students in their courses, their own academic preparation, how they would have altered their academic preparation for their current position, their preceived value of secondary school teaching in their current position, and additional comments about preparation for teaching in the community college. Personel officers at these institutions were surveyed on degrees they require for hiring biology and chemistry instructors, additional qualifications they seek in instructors, and whether they believe secondary school teaching experience to be of benefit for someone considering a community college teaching position.

Major concerns in hiring an instructor are a stong academic preparation in the teaching field and a second major or minor in a related science field. An additional concern is the ability to address the special needs of the diverse student population found in the community college setting. The instructors suggest that programs in science education can help teachers improve their instructional techniques, and 7 6% of the instructors who have taught in secondary schools indicate that this experience had been beneficial in their community college teaching.     

Promoting Inquiry-Based Teaching in Laboratory Courses: Are We Meeting the Grade?

Over the past decade, repeated calls have been made to incorporate more active teaching and learning in undergraduate biology courses. The emphasis on inquiry-based teaching is especially important in laboratory courses, as these are the courses in which students are applying the process of science. To determine the current state of research on inquiry-based teaching in undergraduate biology laboratory courses, we reviewed the recent published literature on inquiry-based exercises. The majority of studies in our data set were in the subdisciplines of biochemistry, cell biology, developmental biology, genetics, and molecular biology. In addition, most exercises were guided inquiry, rather than open ended or research based. Almost 75% of the studies included assessment data, with two-thirds of these studies including multiple types of assessment data. However, few exercises were assessed in multiple courses or at multiple institutions. Furthermore, assessments were rarely based on published instruments. Although the results of the studies in our data set show a positive effect of inquiry-based teaching in biology laboratory courses on student learning gains, research that uses the same instrument across a range of courses and institutions is needed to determine whether these results can be generalized.     

Exploring DNA structure with Cn3D

Researchers in the field of bioinformatics have developed a number of analytical programs and databases that are increasingly important for advancing biological research. Because bioinformatics programs are used to analyze, visualize, and/or compare biological data, it is likely that the use of these programs will have a positive impact on biology education. Over the past years, we have been working to help biology instructors introduce bioinformatics activities into their curricula by providing them with instructional materials that use bioinformatics programs and databases as educational tools. In this study, we measured the impact of a set of these materials on student learning. The activities in these materials asked students to use the molecular structure visualization program Cn3D to locate, identify, or analyze diverse features in DNA structures. Both the experimental groups of college and high school students showed significant increases in learning relative to control groups. Further, learning gains by the college students were correlated with the number of activities assigned. We conclude that working with Cn3D was important for improving student understanding of DNA structure. This study is one example of how a bioinformatics program for visualization can be used to support student learning.     

Teaching the process of science: faculty perceptions and an effective methodology

Most scientific endeavors require science process skills such as data interpretation, problem solving, experimental design, scientific writing, oral communication, collaborative work, and critical analysis of primary literature. These are the fundamental skills upon which the conceptual framework of scientific expertise is built. Unfortunately, most college science departments lack a formalized curriculum for teaching undergraduates science process skills. However, evidence strongly suggests that explicitly teaching undergraduates skills early in their education may enhance their understanding of science content. Our research reveals that faculty overwhelming support teaching undergraduates science process skills but typically do not spend enough time teaching skills due to the perceived need to cover content. To encourage faculty to address this issue, we provide our pedagogical philosophies, methods, and materials for teaching science process skills to freshman pursuing life science majors. We build upon previous work, showing student learning gains in both reading primary literature and scientific writing, and share student perspectives about a course where teaching the process of science, not content, was the focus. We recommend a wider implementation of courses that teach undergraduates science process skills early in their studies with the goals of improving student success and retention in the sciences and enhancing general science literacy.     

Teaching and learning cultures in higher education: a mismatch in conceptions

ABSTRACT

Instructional approaches in higher education that foster learning based on internal values are required with the enrollment of wider and more diverse audiences. The current study explores this challenge with a focus on the relationship between students’ learning cultures and the way instructors’ view them. We interviewed 76 students and six instructors at an established academic institution. Data comprised of 210 students’ and 146 instructors’ utterances that were analyzed using mixed methods. Findings revealed a mismatch of instructors’ conceptions about the learning culture of the typical student, potentially leading to compromises in their teaching practices. We provide evidence that reciprocal relations exist between cultures of teaching and learning, contributing to the wicked challenges of rethinking the role of teachers in reinforcing passive learning cultures in undergraduate education. Adoption of internal-based values teaching approaches can help break this feedback loop.     

Undergraduate research experiences support science career decisions and active learning

The present study examined the reliability of student evaluations of summer undergraduate research experiences using the SURE (Survey of Undergraduate Research Experiences) and a follow-up survey disseminated 9 mo later. The survey further examines the hypothesis that undergraduate research enhances the educational experience of science undergraduates, attracts and retains talented students to careers in science, and acts as a pathway for minority students into science careers. Undergraduates participated in an online survey on the benefits of undergraduate research experiences. Participants indicated gains on 20 potential benefits and reported on career plans. Most of the participants began or continued to plan for postgraduate education in the sciences. A small group of students who discontinued their plans for postgraduate science education reported significantly lower gains than continuing students. Women and men reported similar levels of benefits and similar patterns of career plans. Undergraduate researchers from underrepresented groups reported higher learning gains than comparison students. The results replicated previously reported data from this survey. The follow-up survey indicated that students reported gains in independence, intrinsic motivation to learn, and active participation in courses taken after the summer undergraduate research experience.     

Equity in college physics student learning: A critical quantitative intersectionality investigation

We investigated the intersectional nature of race/racism and gender/sexism in broad scale inequities in physics student learning using a critical quantitative intersectionality. To provide transparency and create a nuanced picture of learning, we problematized the measurement of equity by using two competing operationalizations of equity: Equity of Individuality and Equality of Learning. These two models led to conflicting conclusions. The analyses used hierarchical linear models to examine student's conceptual learning as measured by gains in scores on research-based assessments administered as pretests and posttests. The data came from the Learning About STEM Student Outcomes' (LASSO) national database and included data from 13,857 students in 187 first-semester college physics courses. Findings showed differences in student gains across gender and race. Large gender differences existed for White and Hispanic students but not for Asian, Black, and Pacific Islander students. The models predicted larger gains for students in collaborative learning than in lecture-based courses. The Equity of Individuality operationalization indicated that collaborative instruction improved equity because all groups learned more with collaborative learning. The Equality of Learning operationalization indicated that collaborative instruction did not improve equity because differences between groups were unaffected. We discuss the implications of these mixed findings and identify areas for future research using critical quantitative perspectives in education research.     

Making learning meaningful: facilitating interest development and transfer in at-risk college students

The Teaching for Transformative Experience in Science (TTES) model has shown to be a useful tool to generate learning and engagement in science. We investigated the effectiveness of TTES for facilitating transformative experience (TE), learning, the development of topic interest and transfer of course concepts to other courses employing a quasi-experimental design. Our goal was to determine the effectiveness of TTES compared to an alternative teaching method in a course designed for academically at-risk undergraduate students. Specifically, we explored the impact of TTES for teaching about motivation in a college success course. The results showed that TTES generated TE outside of the biological sciences, increased learning, developed student interest and facilitated self-reported transfer to other courses. The findings have important implications for facilitating learning and motivation in academically at-risk college students, which may subsequently impact college student retention and academic success.     

Instructional practices in reformed undergraduate STEM learning environments: a study of instructor and student behaviors in biology courses

ABSTRACT

Theoretically, organisational culture, instructor training, and learning space design influence how faculty teach STEM courses. Previous studies have used classroom observation protocols to characterise the range of teaching practices in mostly teacher-centered, traditional STEM classrooms. In this study, we examined the classroom behaviour of 13 STEM faculty teaching biology courses in a reformed undergraduate STEM learning environment. Our findings indicate that instructors teaching in this reformed environment guided student learning (58.4?±?1.9%) almost three times more than they presented information (20.0?±?2.2%). Students worked individually or in groups and talked to the whole class (57.1?±?1.8%) 1.5 times more than they received information (35.5?±?1.9%). We found significant positive correlation between ‘instructor presenting’ and ‘students receiving’ information (r?=?0.743, p?=?1.4?×?10^?4) and ‘instructor guiding’ and ‘student working and talking’ in class (r?=?0.605, p?=?7.2?×?10^?5), suggesting that instructors can change their own classroom behaviours and expect concurrent change in their students’ behaviours. Finally, sequencing teaching practices in high active-engagement classrooms showed instructors move and guide student group work and lead whole class discussions before lecturing to students, which could lead to deeper learning of conceptual knowledge. We discuss insights from these findings that have implications for acculturating evidence-based teaching practices in STEM departments.     

The effectiveness of blended online learning courses at the community college level

Whether through the use of online-only or hybrid/blended formats, colleges and universities across the country are increasingly utilizing online platforms as a medium for the delivery of instruction. At the same time, we know little about how student learning outcomes are related to students’ engagement with online instructional formats. In particular, few studies have evaluated online learning in community colleges, and fewer yet have employed an experimental or quasi-experimental design to do so. In this research, we use propensity score matching to compare learning gains between community college students enrolled in blended courses, (courses that combine online instructional delivery with traditional classroom-based instruction) with gains experienced by students receiving only classroom-based instruction. Among students enrolled in blended courses, we also consider which aspects of student use of online instructional materials are most strongly associated with student learning. While some evidence has suggested significantly poorer outcomes for community college students enrolled in online-only courses, our results suggest that students enrolled in blended courses perform similarly, if not better, relative to students in a traditional instructional setting. Implications for practice and research are discussed.     

Kelley Direct (KD) E- learning Toolkit

Conclusion In order to support online teaching and learning better, KD has developed a group of customized tools collectively known as KD E-learning Toolkit. Among these tools, Customized Forums provide instructors with additional means to organize asynchronous discussions; Team Builder and Team Presentation make team building and team collaboration more efficient; Hand-in System greatly reduces instructors’ workload in downloading and uploading student files; and Test Tool allows students to take tests offline. The utility of the Toolkit cuts across many dimensions in course design. For example, the Toolkit can be used in courses with large student enrollments or small class size, in team-based or project-based courses or courses geared towards individual learning; and the Toolkit could be used in most academic disciplines in the Arts, Sciences, Humanities, and in professional education. To support a highly professional student body, Kelly Direct Online Program at Indiana University Kelley School of Business has sought from its inception to acquire and develop learning tools that facilitate asynchronous, interactive learning. The KD E-Learning Toolkit supports this philosophy.     

Using clickers in nonmajors- and majors-level biology courses: student opinion, learning, and long-term retention of course material

Student response systems (clickers) are viewed positively by students and instructors in numerous studies. Evidence that clickers enhance student learning is more variable. After becoming comfortable with the technology during fall 2005-spring 2006, we compared student opinion and student achievement in two different courses taught with clickers in fall 2006. One course was an introductory biology class for nonmajors, and the other course was a 200 level genetics class for biology majors. Students in both courses had positive opinions of the clickers, although we observed some interesting differences between the two groups of students. Student performance was significantly higher on exam questions covering material taught with clickers, although the differences were more dramatic for the nonmajors biology course than the genetics course. We also compared retention of information 4 mo after the course ended, and we saw increased retention of material taught with clickers for the nonmajors course, but not for the genetics course. We discuss the implications of our results in light of differences in how the two courses were taught and differences between science majors and nonmajors.     

Information fluency for undergraduate biology majors: applications of inquiry-based learning in a developmental biology course

Many initiatives for the improvement of undergraduate science education call for inquiry-based learning that emphasizes investigative projects and reading of the primary literature. These approaches give students an understanding of science as a process and help them integrate content presented in courses. At the same time, general initiatives to promote information fluency are being promoted on many college and university campuses. Information fluency refers to discipline-specific processing of information, and it involves integration of gathered information with specific ideas to form logical conclusions. We have implemented the use of inquiry-based learning to enhance and study discipline-specific information fluency skills in an upper-level undergraduate Developmental Biology course. In this study, an information literacy tutorial and a set of linked assignments using primary literature analysis were integrated with two inquiry-based laboratory research projects. Quantitaitve analysis of student responses suggests that the abilities of students to identify and apply valid sources of information were enhanced. Qualitative assessment revealed a set of patterns by which students gather and apply information. Self-assessment responses indicated that students recognized the impact of the assignments on their abilities to gather and apply information and that they were more confident about these abilities for future biology courses and beyond.     

Exploring the Usefulness of Kelly's Personal Construct Theory in Assessing Student Learning in Science Courses

We explore the utility of George Kelly's Personal Construct Theory, specifically his repertory grid technique, to the assessment of student learning in undergraduate science courses. We provide an in-depth review of the assumptions underlying Personal Construct Theory and how these were reflected in the repertory grid technique Kelly developed. We explain how an adapted version of the repertory grid, sharing some yet not all of Kelly's assumptions, was utilised as a research tool in a recent study involving science instructors and their students. We argue that as well as having applicability as an innovative research tool, an adapted version of Kelly's repertory grid is a useful heuristic for university teachers when used as a classroom assessment technique (CAT) and indicate several features it shares with the more widely-known conceptual mapping technique, which has been used in the study of science teaching and learning for many years. We conclude by highlighting several advantages the use of repertory grids has for both students and instructors.     

Researching the Scholarship of Teaching and Learning: An Analysis of Current Curriculum Practices

The purpose of this study was to analyze how instructors designed courses for scholarship of teaching and learning initiatives. The case studies and qualitative analyses of the data revealed that some instructors are approaching teaching as an investigative process. Informed by multiple assessment methods, the participating instructors explored how changes in course designs can improve student learning and development. The results of this study illustrate that these instructors reflected on their course designs and emphasized the quality of student learning and its improvement, which helps to address the public's expectations of higher education institutions as centers of academic excellence.